Regenerable diesel exhaust filter and heater

ABSTRACT

A filter assembly for removing particulates from the exhaust gas of a diesel engine. The filter assembly includes a housing having an inlet pipe which may be coupled to the engine and an outlet pipe which may be open to the atmosphere, and a self-contained filtering mechanism disposed within the housing. An exhaust gas fluid path is defined from the inlet pipe through the self-contained filtering mechanism and out the outlet pipe. Each of the components of the self-contained filtering mechanism are highly resistant to high temperatures, so that the filtering mechanism may be electrically regenerated by heat, produced by a heater operatively associated with the filtering mechanism, which burns off accumulated, typically hydrocarbon, particulates.

BACKGROUND

This application is a continuation-in-part of PCT InternationalApplication Serial No. US93/00022 filed on Jan. 7, 1993 which is acontinuation-in-part of U.S. application Ser. No. 07/817,595, filed onJan. 7, 1992 now U.S. Pat. No. 5,228,891.

The present invention relates to a filter system for purifying theexhaust gases of an internal combustion engine. In particular, itrelates to a regenerating filter for removing particulates from theexhaust gases of a diesel engine.

There is an increasing awareness of the health hazards presented by manycommon air pollutants. Perhaps in response to these concerns,governments are increasingly regulating the exhaust emissions ofvehicles. In the United States, Environmental Protection Agencyrequirements relate to the exhaust of vehicles, rather than the deviceor method used to control the exhaust. Two predominant methods arecurrently used to control emissions; they are the utilization ofalternative fuels, and solid particulate removal, as with a filter.

In particular, diesel engines, such as those utilized in trucks, buses,and passenger cars, produce a tremendous amount of soot. As there are inexcess of 1.2 million diesel-powered vehicles in the United Statesalone, diesel engines pose significant health and air pollutionproblems. Over the next several years, vehicles powered by such dieselengines must meet more and more stringent regulations. As a result,there is increasing interest in the efficient and effective limitationof emission of particulate material, generally carbon and hydrocarbonparticles, from the exhaust gases of diesel engines.

Various types of filtering devices have been proposed to filter dieselengine exhaust. Usually, such devices comprise filter systems whichretain and collect the particulates in the exhaust gas. As sootparticles are reported to range in size upward from 2500 Å (0.25micron), a high efficiency filter is required to effectively filter outsuch contaminants. A number of filters are known. For example, cellularceramic filters and honeycomb filters of porous ceramic material, suchas those disclosed in U.S. Pat. Nos. 4,872,889 and 4,948,403 toLepperhoff et al., have been recognized as being useful in trappingparticulates from exhaust emissions.

However, particulates retained in the filter generally lead to anincrease in the flow resistance in the exhaust and a resultant increasein the back pressure of the exhaust. Excessive back pressure can developquickly, particularly when high efficiency filters are utilized. Thisunacceptable increase in exhaust back pressure can lead to an increasein fuel consumption, and, in extreme cases, to engine shut-off orfailure. This result is particularly troublesome with truck and busdiesel engines inasmuch as any filter of a practical size would quicklybecome loaded and develop high back pressure which would result inengine shut-off.

As a result, it necessary to intermittently regenerate the filter toremove the carbon particles from the filter during operation of thediesel engine. This is generally accomplished by providing sufficientheat to combust the particulates. Consequently, filter materials mustwithstand temperatures of over 600° C. (1112° F.) repeatedly. A numberof methods of regeneration are known, such as the utilization ofelectric heating elements, as disclosed in, for example, U.S. Pat. No.5,053,062 to Barris et al., U.S. Pat. No. 4,791,785 to Hudson et al.,and U.S. Pat. Nos. 4,872,889 and 4,948,403 to Lepperhoff et al. Anothermeans of regenerating the filter includes turbo enriched fuel injectionto raise the temperature in the filter to initiate auto-combustion oftrapped soot particles. These methods may suffer, however, fromdifficulties in the ignition of deeply trapped soot particles duringregeneration or require an excessive energy input to regenerate thefilter material.

Ceramic honeycomb filter designs are particularly susceptible to rapiddevelopment of excessive back pressure. There are a number of additionaldisadvantages, however, associated with the use of ceramic materials.Ceramic materials, particularly filters, are inherently brittle, and,consequently, subject to fracture from shock and mechanical stresses.Therefore, when ceramic materials are used in filters, it is necessaryto design the filters with greater depth thickness than ordinarilydesirable. Further, because ceramic materials are fragile and notdeformable, it is not feasible to utilize standard engineeringedge-sealing, gasketing methods due to the heating that is required.Ceramics are also costly to manufacture as they are difficult to shape.Additionally, inasmuch as the uniformity of ceramic particles isdifficult to control, particularly for sintering and pre-forming,manufacturing quality is difficult to control.

SUMMARY

The general object of the invention is to provide an improved exhaustfilter for diesel engines. A more particular object of the invention isto provide a reliable, high efficiency filter which provides a lowchange in pressure across the filter.

An additional object is to provide an exhaust filter that does notsignificantly impair engine performance. A related object is to providean exhaust filter with reduced susceptibility to development of backpressure.

Another object is to provide an exhaust filter that is highly resistantto heat, and is regenerable.

A further object is to provide an exhaust filter of an uncomplicateddesign that may be easily serviced. A more specific object is to providean exhaust filter that may be easily assembled and disassembled tofacilitate maintenance or replacement of filter elements in the field.

Yet another object is to provide a diesel exhaust purification systemwhich accommodates a large flow of gas but features a small, compactdesign.

Another object of the invention is to provide an exhaust filter assemblywhich facilitates the ignition of trapped soot particles duringregeneration of the filter.

An additional object is to provide a modular diesel exhaust filterarrangement which may be sized to fit a variety of different engines.

In accomplishing these objects, there is provided an improved dieselexhaust filter having a high efficiency, self-contained filterarrangement disposed within a housing that may be connected in-line withthe exhaust system of the vehicle to provide a flow of exhaust gasestherethrough. The housing, which may be of any appropriate shape,includes an inlet pipe, which may be connected to an exhaust pipe fromthe engine, and an outlet pipe, which may be open to the atmosphere.Disposed within the housing is a self-contained filtering means.

In one embodiment of the invention, the filtering means is a flat filterarrangement having inlet and outlet cells and filter elements compressedbetween opposite impervious endplates. Exhaust gas enters the inletcells along the inlet end of the housing, flows through the filterelements, and out of the filter arrangement through the outlet cells tobe exhausted to the atmosphere through the outlet pipe. In anotherembodiment of the invention, a pleated cylindrical filter is utilized,the exhaust gas flowing from the inlet pipe outward through thecylindrical filter from the interior, or, alternately, inward from theperimeter of the cylindrical filter to its interior, and out of thehousing through the outlet pipe. Another embodiment combines the flatand cylindrical filters of the first and second embodiments,respectively, to provide an arrangement where the exhaust gas flowsthrough the flat filters and outward from the interior of thecylindrical filter to its perimeter to be passed to the atmospherethrough the outlet pipe. Another embodiment of the invention comprises ahousing having a rectangular plenum having an open top portion intowhich seats a topplate having substantially flat and upwardly andoutwardly extending sides. This embodiment utilizes a flat filterarrangement, the components of which are compressed between the lower,inner surface of the plenum and the flat surface of the topplate by nutsand carriage bolts that extend through openings in the flat surface ofthe topplate, the lower surface of the plenum, and the components of thefilter arrangement. Another embodiment of the invention comprises asimilar flat filter arrangement, and housing comprising a plenum havingdual components that are secured together along outwardly extendingflanges by bolts. Flat plates, each having an outwardly extending pipeare secured to the ends of the plenum to seal the housing.

Another embodiment of the invention includes a housing having an inletpipe and an outlet pipe, which defining an exhaust gas flow path throughthe housing, and a filter arrangement is disposed within the gas flow.The filtering arrangement includes a plurality of inlet cells,microporous filter elements and outlet cells, which are alternatelyarranged with at least one microporous filter element disposed betweeneach inlet cell and adjacent outlet cell. A portion of the filterelements extend past the inlet and outlet cells. The inlet and outletcells, and the microporous filter elements comprise materials that areresistant to high temperatures such that the filtering arrangement maybe regenerated by heat.

In any of the embodiments of the present invention, the filter assemblymay further include an insulating material coupled to the housing. Theinsulating material is resistant to the high temperatures to which itmay be exposed during regeneration of the filtering means. Theinsulation of the housing, in addition to lessening heat dissipationwithin the plenum, serves to enhance the safety of the filter assemblyby reducing the surface temperature of the housing.

Each of the filter arrangements utilizes materials that are highlyresistant to excess temperature so that the exhaust filter may beregenerated by heat provided by any appropriate method. Further, thefilters, while having a much higher efficiency than present ceramic andmetal trap filter designs, provide effective filtration of soot expelledfrom the diesel engine with a minimal pressure drop across the filter.The filter arrangements preferably comprise a fiber filter sandwichedbetween woven wire mesh. The fiber filter preferably comprises quartz,borosilicate-E or aluminosilicate.

Further, the structure of the exhaust filter is such that it may beeasily disassembled to facilitate service, even after the device hasbeen installed on a vehicle. The housing includes a plenum and at leastone removable endplate. Once the endplate has been disassembled from theplenum, the self-contained filter arrangement may be removed to permitreplacement or further cleaning. The filter arrangement may then bereinserted and the housing easily reassembled.

The exhaust filter may also incorporate an electric heater in theplenum, which may be operated from an electric source in the vehicle.The electric heater may serve to heat the plenum in order to initiatethe regeneration of the filter assembly.

An exhaust gas filter assembly for removing particulates from theexhaust gas of an engine in accordance with the present inventionincludes a housing having an inlet pipe configured to receive theexhaust gas from the engine and an outlet pipe configured to ventexhaust gas to the atmosphere and defining an exhaust gas flow paththrough the housing. A filter arrangement is disposed within the housingin the gas flow path. The filter arrangement includes a plurality ofinlet cells, microporous filter elements, and a plurality of outletcells which are alternately arranged. At least one microporous filterelement is disposed between each inlet cell and adjacent outlet cell.The inlet and outlet cells, and the microporous filter elements includematerials that are resistant to high temperatures for allowing thefilter arrangement to be regenerated by heat. At least one of the inletcells or outlet cells is electrically conductive. The exhaust gas filterincludes a heater associated with the filter arrangement to regeneratethe filter arrangement by heating the filter arrangement or gas in thehousing to combust the particulates removed from the exhaust gas of theengine. The heater includes an electrical connection means forelectrically connecting the electrically conductive inlet cell or outletcell to an electrical power source.

An exhaust gas filter assembly in accordance with the invention may alsoinclude a housing having an inlet pipe for receiving exhaust gas and anoutlet pipe for venting exhaust gas to the atmosphere. A filterarrangement is disposed within the housing and includes a plurality ofinlet cells, microporous planar filter elements and outlet cells whichare alternately arranged with at least one microporous planar filterelement disposed between each inlet cell and adjacent outlet cell. Theinlet and outlet cells, and the microporous planar filter elementscomprise materials that are resistant to high temperatures so that thefilter arrangement may be regenerated by heat. At least one of thefilter elements includes a filter support and a filter medium. Anelectrically resistive heating wire is mounted to the filter support toregenerate the filter arrangement by heating the filter arrangement orgas in the housing to combust the particulates removed from the exhaustgas.

An exhaust gas filter assembly in accordance with the invention may alsoinclude a housing having an inlet pipe for receiving exhaust gas and anoutlet pipe for venting exhaust gas to the atmosphere. A filterarrangement is disposed within the housing and includes a plurality ofinlet cells, microporous planar filter elements and outlet cells whichare alternately arranged with at least one microporous planar filterelement disposed between each inlet cell and adjacent outlet cell. Theinlet and outlet cells, and the microporous planar filter elementscomprise materials that are resistant to high temperatures so that thefilter arrangement may be regenerated by heat. At least one of thefilter elements includes a filter support and a filter medium. Anelectrically resistive heating wire is mounted to the filter medium toregenerate the filter arrangement by heating the filter arrangement orgas in the housing to combust the particulates removed from the exhaustgas.

An exhaust gas filter assembly according to the invention also includesa housing having an inlet and outlet pipe. A filter arrangement isdisposed within the housing and includes a plurality of inlet cells,microporous filter elements and outlet cells which are alternatelyarranged with at least one microporous filter element disposed betweeneach inlet cell and adjacent outlet cell. The inlet and outlet cells,and the microporous filter elements comprise materials that areresistant to high temperatures such that the filter arrangement may beregenerated by heat. At least one of the filter elements includes afilter support and a filter medium. An electrically resistive heatingwire is disposed within at least one of the microporous filter elementsand mounted to the filter medium to regenerate the filter arrangement byheating the filter arrangement or gas in the housing to combust theparticulates removed from the exhaust gas.

BRIEF DESCRIPTION OF THE DRAWINGS

The foregoing and other features of the present invention will becomeapparent to one of ordinary skill in the art to which the inventionpertains from the following detailed description when read inconjunction with the drawings, in which:

FIG. 1 is a perspective view of an exemplary filter system embodying theinvention;

FIG. 2 is an exploded view of the filter system of FIG. 1;

FIG. 3 is an exploded view of a portion of the filter arrangement ofFIG. 2;

FIG. 4 is a cross-sectional view of the filter system taken along line4--4 in FIG. 1;

FIG. 5 is a cross-sectional view of an alternate embodiment of thefilter system shown in FIG. 1;

FIG. 6 is a cross-sectional view of an alternate embodiment of thefilter system shown in FIG. 1;

FIG. 7 is a cross-sectional view of the filter system taken along line7--7 in FIG. 6;

FIG. 8 is a view of an alternate embodiment of the embodiment of thefilter system shown in FIG. 1;

FIG. 9 is a cross-sectional view of the filter system taken along line9--9 in FIG. 8;

FIG. 10 is a perspective view of the filter arrangement of FIG. 9;

FIG. 11 is a top view of an inlet cell of FIG. 10;

FIG. 12 is a top view of an alternate embodiment of inlet cell;

FIG. 13 is a side view of the inlet cell taken along line 13--13 of FIG.12;

FIG. 14 is a side view of the inlet cell taken along line 14--14 of FIG.12;

FIG. 15 is a perspective view of an alternate embodiment of theinvention of FIG. 1;

FIG. 16 is a partially cutaway top view of the inlet end of an alternateembodiment of the filter system of the present invention;

FIG. 17 is a cross-sectional view of the filter system of FIG. 16;

FIG. 18 is a cross-sectional view of a modification of a portion of thehousing of the filter system of FIG. 16;

FIG. 19 is a cross-sectional view of an alternate embodiment of thefilter system of the present invention;

FIG. 20 is a cross-sectional view of a filter system;

FIG. 21 is a top view of an inlet cell;

FIG. 22 is an exploded view of a portion of a filter arrangement; and

FIG. 23 is a cross-sectional view of an alternate filter system.

While the invention will be described in connection with certainpreferred embodiments, there is no intent to limit it to thoseembodiments. On the contrary, the intent is to cover all alternatives,modifications, and equivalents included within the spirit and scope ofthe invention as defined by the appended claims.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Turning now to the drawings, there is shown in FIG. 1 an exhaust filtersystem 20 for use in the exhaust system of a diesel powered vehicle. Thefilter system 20 includes a housing 22 having an inlet pipe 24 and anoutlet pipe 26. The housing 22 may be connected in-line with the exhaustsystem of a diesel powered vehicle to provide a flow of exhaust gasesfrom the engine into the inlet pipe 24, through the housing 22, and outof the outlet pipe 26 to the atmosphere. In a currently preferredembodiment, the inlet and outlet pipes 24, 26 are on the order of twoinches, or fifty millimeters in diameter.

In accordance with one aspect of the invention, there is provided aself-contained filter arrangement 28 in line with the gas flow throughthe housing 22, as shown in the exploded view in FIG. 2. The filterarrangement 28 provides high efficiency filtration of the gases passingtherethrough, while providing a relatively low pressure drop across thefilter system 20. Further, the filter arrangement 28, and, indeed, thefilter system 20 is comprised of materials that are highly resistant toheat required for the regeneration process.

In the embodiment shown in FIGS. 1-4, the housing 22 comprises a plenum30, which is generally configured as a rectangular parallelepiped. Itwill be appreciated, however, that the housing 22 as well as theself-contained filter arrangement 28, may be of a suitable alternategeometric design. In the preferred embodiment, the inlet pipe 24 and theoutlet pipe 26 are formed integrally with the endplates 32, 34,respectively. The endplates 32, 34 are provided with flanges 33 forcoupling the endplates 32, 34 to the plenum 30 by way of bolts 36 orother suitable fastening devices, which extend through the flanges 33and the plenum 30. Accordingly, those skilled in the art will appreciatethat the housing 22 may be easily disassembled for maintenance orreplacement of the filter arrangement 28, even after installation.Although the housing 22 may be of any appropriate dimensions, acurrently preferred design is on the order of eight inches (20.32 cm) byfifteen inches (38.1 cm) by six inches (15.24 cm). However, for largerengines, or different vehicles, these dimensions may be effectivelyaltered to different proportions to fit the space provided.

The housing 22 may be coupled to an insulating material, which isresistant to the high temperatures to which such material may be exposedduring regeneration of the filtering arrangement 28. Typically, theplenum is wrapped with the insulating material and preferably all of theouter side of the housing is wrapped with the insulating material. In apreferred embodiment, the insulation may be sandwiched between inner andouter walls of the housing 22. FIG. 18 shows a cross-sectional view of aportion of the plenum 30 of this embodiment. The insulating material 210is sandwiched between inner and outer walls 30A, 30B of the plenum 30.In an alternate embodiment, the insulating material may be a blanketwrapped around the interior or exterior of the housing 22. Suitableinsulation material may comprise inorganic fibers capable ofwithstanding the temperatures produced during regeneration of thefiltering means, e.g., calcium silicate fibers.

The presence of the layer of insulating material minimizes heat lossfrom the housing. This allows the high temperatures required to burn offsoot collected in the filtering means to be achieved with a lower energyinput. By preventing the dissipation of heat from the filter assembly,the insulation also increases the efficiency of the soot burn off oncecombustion of the soot has been initiated and enhances the safety of thefilter assembly by reducing the surface temperature of the housing.

Further, in order to facilitate installation of the filtering system 20on the vehicle, the housing 22 may be provided with mounting brackets(not shown). The mounting brackets may be formed integrally with one ofthe components of the housing 22, or may be formed as separatecomponents, which may be then be coupled to the housing 22.

The self-contained filter arrangement 28 is shown in greater detail inFIG. 3. The filter arrangement 28 is configured as a rectangularparallelpiped and generally comprises an assembly of inlet cells 40,outlet cells 42, and filter elements 44 compressed between oppositeimpervious endplates 46, 48, which may be integrally formed with theinlet and outlet cells 40, 42, as shown in FIG. 3. The inlet and outletcells 40, 42, which may be identical to each other, are relatively thinstructures. The configuration of the self-contained filtering meansprovides access to both sides of the microporous filter elements,thereby increasing the soot load capacity and life of the filterassembly.

Each cell 40, 42 includes four frame members 40a-40d, 42a-42d joined ina rectangular frame and a number of support members. In the embodimentillustrated in FIG. 3, each cell 40, 42 includes two support members40e-40f, 42e-42f connected between opposite frame members 40b, 40d, 42b,42d. However, any number of support members arranged in any appropriateconfiguration or geometry may be utilized. Small cells may not requiresupport members.

For both the inlet and outlet cells 40, 42, one of the opposite framemembers 40b, 42d contains several apertures 50, 52, which interconnectthe exterior of the cells 40, 42 and the interior or internal spaces 54,56 between the frame and support members 40a-40f, 42a-42f, respectively.In the embodiment shown in FIGS. 2-4, the apertures 50, 52 are of arectangular shape. The rectangular shape provides highly efficient airflow through the cells 40, 42. It will be appreciated, however, that theapertures 50, 52 may be of any appropriate shape.

Likewise, the cells 40, 42 may be fabricated by any appropriate method;for example, the cells 40, 42 may be milled, machined, or cast.According to one low cost method, the cells 40, 42 may be flame cut ormachined from flat sheet metal. The apertures may then be drilled in oneof the frame members. Another low cost method is to cast the cells insteel or iron.

The inlet and outlet cells 40, 42 are distributed alternately within thefilter arrangement 28 with the frame and support members 40a-f of theinlet cells 40 lying similarly to the frame and support members 42a-42fof the outlet cells 42, respectively. The inlet and outlet cells 40, 42are further arranged so all of the inlet apertures 50 and none of theoutlet apertures 52 open onto one surface of the filter arrangement 28,defining an inlet surface 58 facing the endplate 32, as shown in FIG. 2.In the exemplary filter system 20, all of the outlet apertures 52 openonto the opposite surface of the filter arrangement 28, defining anoutlet surface 60 facing 180 degrees from the inlet surface 58.Alternately, the outlet apertures 52 may open onto a side surface orsurfaces of the filter arrangement 28, or any appropriate combinationthereof, so long as the inlet apertures 50 are sealed from the outletapertures 52.

Returning now to FIG. 3, disposed between the inlet and outlet cells 40,42, the filter elements 44 each comprise one or more layers of amicroporous filter 57 for removing particulate contaminants, e.g.,carbon and hydrocarbon particles. The filters 57 are exposed toexcessive temperatures, as well as hydrocarbons, chlorides, and acidforming exhaust. Consequently, the filter material must be highlyresistant to high temperatures and chemical deterioration. A variety ofmicroporous filter materials or combinations thereof are suitable foruse in the filter element 44, including ceramic fibers, porous metalfiber, or porous metal powder. Such materials as high purity silica,aluminosilicate or borosilicate-E glass, powdered metal alloys, boron,and carbon fibers, as well as other synthetic fibrous or matrix-formingmaterials may likewise be used. In general, any inorganic fibrousmaterial that has a service temperature of at least 1200° F. may be usedif the material is capable of forming a filter media that will permitthe efficient removal of solid contaminants, such as soot particles, ata low pressure drop. It will be appreciated, however, that the filtermedium utilized preferably provides a high efficiency filter and is ableto withstand repeated heating to high temperatures. Typically, thefilter elements of the present invention comprise fibers having anaverage fiber diameter of from about 0.25 micron to about 15 microns andpreferably of from about 0.5 micron to about 2.0 microns. Additionally,the filter element is preferably fashioned as a compressible material toallow the filter elements to be sealingly compressed when pressure isapplied to the inlet and outlet cells.

A preferred filter 57 comprises quartz fiber, which is able to withstandextremely high temperatures, and has a high efficiency. Quartz fibers,such as Manville Corning type 104, 106, 108, 110 grades, or blendsthereof, may be used. This filter is advantageous in that it blendsfibers from under one-half micron in diameter to four microns into ahighly porous sheet with low air resistance, while retaining integritywithout the addition of binders. Further, these quartz fibers havemelting points over 2500° F., and a wide range of chemical resistance.

Borosilicate-E glass fibers, aluminosilicate fibers orchromium-containing aluminosilicate fibers are also preferred asmaterials which may be used in the filter elements of the presentinvention. These materials are commercially available in blends of veryfine fibers. For instance, borosilicate-E glass fibers are commerciallyavailable in a variety of average fiber diameters, such as 104, 106 and108B grade fibers, available from Johns-Manville Corporation. The filterelements 57 may preferably include a blend of borosilicate-E glassfibers having an average fiber diameter of 0.65 microns and a surfacearea of 2.3 m² /g. Borosilicate-E glass fibers have a servicetemperature of 1200° F., a softening point of over 1500° F., andexcellent chemical resistance. Aluminosilicate fibers andchromium-containing aluminosilicate fibers, such as are available fromJohns-Manville Corporation with an average fiber diameter of 3-4microns, may also be used in the filter elements of the presentinvention. Aluminosilicate fibers and chromium-containingaluminosilicate fibers have melting points above 3200° F., and a widerange of chemical resistance.

It will likewise be appreciated that alternate filter arrangements maybe utilized. One or more grades of filters may be utilized to act as aprefilter. For example, the filter arrangement may include amulti-layered structure, where the first layer to be contacted by theexhaust gas flow has a larger pore size than the adjacent downstreamlayer. This arrangement provides efficient removal of soot particles ata low pressure drop while making the filter element less susceptible toclogging. Such arrangements may serve to extend the life of the filters.

Further, filter element 44 may further comprise support elements 59which may be provided adjacent the microporous filters 57 in order toprovide additional support thereto, as shown in FIG. 3. In general, anymetal mesh, which is capable of providing support to the areas of thefilter elements unsupported by the frame members of the inlet and outletcells, may be used. Preferably, the support elements are able towithstand the temperatures produced during the regeneration of thefilter elements and typically have a service temperature of at least1200° F. In some applications, where the filter assembly is subjected tohigher temperatures during use, a service temperature of at least 1500°F. is preferred. Currently, preferred embodiments of the inventionutilize a woven metal wire mesh, sintered metal fibers, or a sintered,woven metal mesh, such as RIGIMESH, a product available from PallCorporation. Other support materials may also be suitable as supportelements 59, so long as such materials are able to withstand extremelyhigh temperatures and do not result in rapid development of excessiveback pressure. The woven wire mesh is typically formed of a metal suchas a carbon steel or low-alloy steel. Woven wire mesh formed fromstainless steel (e.g., 304, 316 or 347 stainless steel) or higher alloysmay also be used, particularly where enhanced corrosion resistance isdesired. Mesh sizes such as 100 mesh, 90×100 mesh or 70 mesh aretypically used. These mesh sizes have a very fine wire size and a poresize that is small enough to retain the fibers of the filter element butlarge enough to avoid creating a large pressure drop across the filterelement. A porous metal media, such as PMM media, available from PallCorporation, may likewise be suitable.

The impervious endplates 46, 48 are preferably fashioned from sheetmetal to provide additional structural integrity. Each endplate 46, 48is located adjacent an inlet or outlet cell, 40, 42, preferably with agasket or other supplemental sealant disposed between them.

To compress the filter elements 44 between the inlet and outlet cells40, 42 and to provide structural integrity to the self-contained filterarrangement 28, the endplates 46, 48 are disposed on opposite ends of aninterconnecting frame assembly 64. While a variety of interconnectingframe assemblies 64 may be suitable, including a spring biased clampingassembly, in the exemplary exhaust filter system 20, the interconnectingframe assembly 64 comprises tie rods or carriage bolts 66 runningthrough holes 68 in the corners of the cells 40, 42 and endplates 46, 48and through cut-outs or holes 70 in the corners of the filter elements44. Wing nuts 72 are threaded onto the threaded ends of the carriagebolts 66 and may be tightened to provide the desired compression.

Gaskets may be provided between the filter elements 44, the supportscreens 59, and the inlet and outlet cells 40, 42 to eliminate orminimize leakage. However, the fine fiber materials of the filterelements 44 and openings in the mesh support screen 59 may seal togetherin a manner that prevents leakage, thus eliminating the need for gasketmaterials in these locations.

A gasket 74, as shown in FIG. 2, is disposed between the plenum 30 andthe filter arrangement 28 to prevent leakage of the air from betweenthem. The gasket 74 may also dampen vibrations and noise. The gasket 74may be formed of any suitable high temperature material, includingquartz sheets, magnesium fiber, or other mineral compositions.Alternately, the gasket 74 may be a commercial high temperaturemetallic-type gasket, such as, for example, the type available fromFlexetallic Company. Likewise, the gasket 74 may be constructed of anyappropriate cross-section. For example, metal gaskets may be constructedof a ">" cross-section, wherein the deflection of the open end willcreate a self-adjusting seal between the two surfaces. Such an "elastic"metal seal would also accommodate variations of manufacturing tolerancesof the components.

As shown in FIG. 4, from the inlet apertures 50, the exhaust flowsgenerally parallel to the adjacent filter elements 44 into the interioror internal spaces 54 of the inlet cells 40. It then changes directionand passes through either of the adjacent filter elements 44 whereparticulate contaminants are removed. After passing through the filterelements 44, the purified air flows into the interior or internal spaces56 of the outlet cells 42 and again changes direction, flowing generallyparallel to the adjacent filter elements 44 through the outlet apertures52.

The air is evenly distributed along the filter elements 44 as it flowsgenerally parallel to the filter elements 44. The air then flowssubstantially perpendicularly through the filter elements 44. In thisway, particulates are substantially evenly distributed along the filterelements 44.

The filter arrangement 28 may include a large number of filter elements44, and, therefore, present a large filtering area, in a relativelysmall space. Further, as the adjacent frame members and filters elements44 provide sufficiently large contact area, leakage of air between theframe members and the filter elements 44 is prevented when the assemblyof cells 40, 42 and filter elements 44 is compressed by tightening thewing nuts 72 onto the carriage bolts 66. Thus no gaskets or supplementalsealants are required between the filter elements 44 and the inlet oroutlet cells 40, 42.

It will be appreciated by those in the art that the self-containedfilter arrangement 28 is easy to service. With either of the endplates32 or 34 removed, as explained above, the self-contained filterarrangement 28 may be easily removed from the plenum 30. One or more ofthe filter elements 44 may be removed and cleaned or replaced simply byloosening the wing nuts 72 on the carriage bolts 66. The flexible filterelements 44 may be removed from the filter arrangement 28 by simplyloosening the wing nuts 72, rather than completely removing them,inasmuch as the corners of the filter elements 44 have cutouts 70,rather than holes. Once the filter elements 44 have been reinserted inthe filter arrangement 28, the wing nuts 72 are than tightened onto thecarriage bolts 66 until the filter elements 44 are again adequatelycompressed against the inlet and outlet cells 40, 42.

FIG. 19 shows an alternative embodiment of the present invention whichis configured substantially as in the first embodiment of the presentinvention and those elements corresponding to elements in the firstembodiment of the present invention retain the reference numerals. Incontrast to the first embodiment, in which the configuration of thefilter elements is substantially parallel (see e.g., FIG. 4), theembodiment shown in FIG. 19 includes "wedge-shaped" inlet and outletcells 40x, 42x. The inlet cells 40x have inlet end frame members 220that are thicker than the blind outlet end frame members 221. Similarly,the outlet cells 42x have outlet end frame members 222 that are thickerthan the blind inlet end frame members 223. The side frame members (notshown) of the inlet and outlet cells are tapered accordingly. For agiven number of filter elements, this configuration permits theconstruction of a filter assembly having smaller external dimensionsthan would be possible with an assembly having the parallel filterelement configuration.

Another embodiment of the invention is shown in FIGS. 16 and 17. Thefilter assembly of this embodiment is configured substantially as in thefirst embodiment of the present invention and those elementscorresponding to elements in the first embodiment of the presentinvention retain the reference numerals. As shown in FIGS. 16 and 17,the housing 22 includes a diffuser baffle 200. The inlet chamber 204 maybe partitioned by a diffuser baffle 200 into an outer inlet chamber 202communicating with the inlet pipe, and an inner inlet chamber 203communicating with the inlet cells. The baffle 200 has perforations 206therethrough and comprises materials that are resistant to the hightemperatures that may be produced during regeneration of the filteringarrangement. Preferably, the total area of the perforations 206 is noless than about 25% and preferably about one-half the total surface areaof the baffle 200. In a typical embodiment of the invention, the baffle200 has 1/4 inch (0.635 cm) diameter perforations 206, the total area ofwhich is about 50% of the total surface area of the baffle 200. Thebaffle 200 serves to better distribute incoming gases in the inletchamber 204 without significantly increasing back pressure in theexhaust system. This allows higher incoming exhaust gas velocities to beaccommodated and enhances the efficiency of the filter system.

The filter arrangement 28, a portion of the filter element 57 extendspast the inlet and outlet cells 40, 42. In one embodiment, the filterarrangement includes a filter support element 59 disposed along eachside of each filter element 57. In a preferred embodiment, the filterelement 57 is disposed between two adjacent support elements 59, whichmay be fastened together, e.g., with staples, along the inlet edge 207to prevent damage to the filter element 57. Preferably, portions of thefilter element 57 and the filter support element 59 disposed adjacentthe microporous filter element 57, extend past the inlet and outletcells 40, 42 into the inlet chamber 204 to form an initiator section201. The initiator section 201 extends a sufficient distance beyond theinlet and outlet cells 40, 42, typically, about 1/2 inch (1.27 cm) to 1inch (2.54 cm), to permit the initiator section 201 to be heated byentering exhaust gas without a substantial dissipation of heat, thereby,to facilitate combustion of the solid contaminants. The inlet cells 40,the outlet cells 42, the microporous filter elements 57, and the filtersupport elements 59 comprise materials that are resistant to hightemperatures such that the filtering arrangement may be regenerated byheat.

During operation, exhaust gas flows from the inlet port into inletchamber 204, past initiator sections 201, into the inlet cells 40,through the filter elements 57 and filter support elements 59 and outthrough the outlet cells 42. Solid contaminants, such as soot particles,are collected on the initiator sections 201 as well as on the portionsof the filter elements 57 between the inlet and outlet cells 40, 42. Theinitiator sections 201, which extend into the inlet chamber 204 contacthot incoming gases before heat can be dissipated through the inlet andoutlet cells 40, 42. This allows the initiator sections 201 to be heatedmore rapidly and to a higher temperature than the remaining portions ofthe filter elements and support elements during the regeneration phaseof a filter cycle. The initiator sections facilitate the ignition ofsoot particles during the initial stage of the regeneration phase and asa result, the efficiency of combustion of trapped soot particles isenhanced.

An alternate embodiment of the invention is shown in FIG. 5. In thisembodiment, the housing 22A comprises a generally cylindrical shapedplenum 30A to which the inlet endplate 32A is secured by nuts and bolts36A along an outwardly extending flange 80. The self-contained filterarrangement 28A is likewise of a generally cylindrical shape. In orderto retain the filter arrangement 28A in an appropriate position withinthe housing 22A, post spacers 84 are provided along the inlet side ofthe housing 22A. It will be appreciated that the incoming exhaust flowsinto the housing 22A through the inlet pipe 24A, past the post spacers84, and through the filter arrangement 28A, and out of the outlet pipe26A.

The cylindrical filter arrangement 28A is preferably of pleated design,sandwiching a filter medium 57A between alloy mesh supports 59A.Preferably, filter medium 57A may include Tissuquartz™, sandwichedbetween stainless steel 40-60 mesh 59A, of the types available from PallCorporation. Other preferred filter media comprise quartz fibers,borosilicate-E fibers, aluminosilicate fibers or chromium-containingaluminosilicate fibers.

Another embodiment of the invention, which is shown in FIGS. 6 and 7,provides a combination of a flat filter 90, as in the first embodiment,and a cylindrical filter 92, as with the second embodiment in a singleexhaust filter system. The flat filter 90 may be supported on a flatframe 94 within the housing, while the cylindrical filter 90 may be heldin position by the post spacers 84B. It will thus be appreciated, thatair enters the housing 22B through the inlet pipe 24B, passes throughthe flat filter 90 and the cylindrical filter 92, and passes out of thehousing 22B through the outlet pipe 26B to the atmosphere. As with theembodiments above, the housing 22B may include endplates that may besecured to the plenum by any appropriate method.

Another embodiment of the invention is shown in FIGS. 8-11. As shown inFIG. 8, the filter system 20C includes a housing 22C having an inletpipe 24C and an outlet pipe (not shown). As shown more clearly in FIG.9, the housing 22C comprises a plenum 100 having a rectangular box shapewith an open top. The housing 22C further comprises a topplate 102having a flat surface 104 and upwardly and outwardly extending sides106. The lower surface 108 of the plenum 100 and the topplate 102 areprovided with corresponding holes 110, 112 through which tie rods orcarriage bolts 114 may be inserted. Nuts 116 may then be tightened ontothe bolts 114 to tighten the topplate 102 onto the plenum 100 and securethe components together. Those skilled in the art will appreciate thatas the topplate 102 is pressed downward within the open top of theplenum 100, the upwardly and outwardly extending sides 106 of thetopplate 102 will form a seal between the plenum 100 and the topplate102.

Disposed within the plenum 100 is a self-contained filter arrangement28C, which is shown in more detail in FIG. 10. The filter arrangement28C comprises an arrangement of inlet and outlet cells 40C, 42C, filterelements 44C, and support screens 59C, similar to those shown in FIGS.2-4. To compress the components of the filter arrangement, thecomponents are provided with a plurality of openings 118, similar to theholes 68 and holes 70 in the embodiment shown in FIGS. 2-4.

As shown in FIG. 9, the assembly bolts 114 may be inserted through theopenings 110 in the lower surface 108 of the plenum 100, the openings118 of the filter arrangement 28C, and the openings 112 in the topplate102 and the nuts 116 tightened down to assemble the filter system 20C.In this embodiment, the system 20C may be assembled without the use ofgaskets, as the filter arrangement 28C seats directly against the lowersurface of the plenum 100 and the topplate 102, and tightening theassembly bolts 114 and nuts 116 compress the assembly, including thefilter elements 44C, cells 40C, 42C, and support screens 59C. This typeof arrangement provides easier maintenance and extends the life of thesystem 20C.

Alternate methods of sealing the arrangement may be utilized that do notnecessarily provide for easy field maintenance. For example, a method ofsealing porous metal support screens and sintered filters is by swagingthe edges with a forming press and dies. Alternately, metal edges may besealed by welding.

Returning now to the filter arrangement 28C shown in FIGS. 9-10, it maybe seen that the inlet apertures 50C and outlet apertures (not shown)are round. The inlet and outlet cells 40C, 42C may be more easilyunderstood with reference to FIG. 11, which shows an inlet cell 40C. Itwill be appreciated, however, that the outlet cell 42C may be of asimilar construction. During operation, gas enters the cell 40C throughthe apertures 50C and flows parallel to the support members 40eC-40fC,passes through the support screens 59C and the filter element 44C, andenters the outlet cell 42C to be passed out of the filter arrangement28C.

An alternate inlet/outlet cell 40D arrangement is shown in FIGS. 12-14.In this arrangement, gas enters the cell 40D through apertures 50D. Asillustrated in FIG. 13, the apertures are round; the apertures, however,may be of an alternate configuration. It will be appreciated that inthis configuration, rather than flowing parallel, the gas flows throughthe cell 40D substantially perpendicularly to the support members40eD-40fD.

Therefore, in order to provide a smooth flow of gas through the cell40D, the support members 40eD-40fD are of a configuration that permitsthe gas to flow perpendicularly past the support member. Althoughalternate designs may be appropriate, the "alternating step" designshown in FIG. 14 is particularly suitable for permitting gas flow pastthe support member 40eD-40fD by way of openings 120.

Thus, during operation, gas flows into the cell 40D through theapertures 50D. The gas may then flow directly through the adjacentsupport screens and filter element (not shown), or, may pass one or moresupport members 40eD-40fD by way of openings 120 and then flow throughthe adjacent support screens and filter element. It will be appreciatedthat if the gas flows past only one support member 40eD of the inletcell 40D or flows directly through the adjacent support screens andfilter element, the gas must pass similarly one or more similar supportmembers of the outlet cell before flowing out of the apertures of theoutlet cell (not shown).

Another embodiment of the invention is shown in FIG. 15. In thisembodiment, the housing 22E comprises a substantially rectangularlyshaped plenum 30E that is formed in two mating sections 124, 126 withoutwardly extending flanges 128, 130. In order to secure the sections124, 126 together, nuts 134 and bolts 132 are tightened together throughopenings in the flanges 128, 130. The housing 22E further comprisesendplates 32E (the outlet endplate is substantially identical to theinlet endplate), which include a flat plate 136 from which extends aninlet pipe 24E or outlet pipe (not shown) for coupling to the exhaustsystem. The flat plate 136 is coupled to the plenum 30E by anyappropriate method to provide a seal of the mating surfaces of thesections 124, 126. In the embodiment shown, the flat plate 136 is boltedto the plenum 30E. The filter arrangement 28E may be of any of thedesigns discussed above.

A test, which was conducted to determine the ability of a specificembodiment of the present invention to efficiently remove solidcontaminants from diesel exhaust, is described in the example set forthbelow. This example is offered by way of illustration and not by way oflimitation.

EXAMPLE 1 Efficiency of Diesel Exhaust Solid Contaminant Removal

A test was carried out to determine the ability of a filter assembly ofthe present invention to remove solid contaminants from the exhaustgases of a diesel engine. The filter assembly was fitted on the exhaustdischarge of a Lombardini 6LD 435/B1 monocylindrical, direct injection,4 phase, air cooled type diesel engine. The engine, which isrepresentative of the "Light Duty" class of diesel engines, was run attwo air/fuel ranges on a stationary bench. The filter assembly wasconfigured substantially as shown in FIG. 1-4 and included microfibrousfilter elements disposed between two woven wire mesh support elements.The filter elements were formed from borosilicate-E glass fibers havingan mean fiber diameter of 0.65 micron and a surface area of 2.3 m² /g.The support elements were made of a 90×100 woven wire mesh of 304stainless steel. The filter arrangement contains 35 filter elements,each of which have an exposed area of about 1.4 square feet (1300 squarecm), since both sides of each filter element are exposed.

During the test, engine discharge temperatures, hydrocarbon and NO_(x)gas emissions, solid contaminant output and the pressure differencebetween the inlet and outlet of the filter assembly were measured. Theengine was run for a period of about 150 minutes, during which thefilter assembly demonstrated close to 100% solid contaminant removal.This highly efficient removal of solid contaminants was achieved whilemaintaining a pressure drop of less than 150 mm (H₂ O) across the filterassembly. During the test, the filter had no influence on hydrocarbon orNO_(x) emissions and did not affect the performance of the engine, bothin terms of specific consumption and torque.

In accordance with another aspect of the invention, a heater may beincorporated in an exhaust gas filter system to facilitate regenerationof the filter assembly. The heater preferably heats to a sufficienttemperature to facilitate combustion of the particulates in the filtersystem, for example, a temperature which ignites particulates in thefilter elements, typically a temperature of up to about 600° C. or more.The heater may heat the particulates via any suitable mechanism. Theheater may radiantly heat the particulates directly; the heater may heatthe filter arrangement which in turn conductively heats theparticulates; and/or the heater may heat the gas in the housing orfilter arrangement which in turn convectively heats the particulates.

The heater may be variously configured. For example, the heater maycomprise a burner mounted to the housing or the filter arrangement, afuel line extending between a fuel source and the burner, and a controlarrangement including various valves and pilots for delivering acombustible fuel to the burner and igniting it. Fuel may be delivered tothe burner recurrently or continuously. The burner may include aplurality of fuel outlets, disposed, for example, on a manifold or indifferent portions of the housing or the filter arrangements. Fuel maybe delivered to the fuel outlets and ignited substantiallysimultaneously or sequentially under the control of the controlarrangement.

In preferred embodiments, the heater comprises an electrical resistanceelement and an electrical connection arrangement extending between theelectrical resistance element and a source of electrical energy. Theelectrical resistance element may be any element which, upon beingsupplied with electrical energy, heats to a sufficient temperature tofacilitate combustion of the particulates. The electrical resistanceelement may be an electrically conductive component of the filter systemitself, such as the baffle or the filter support. However, hightemperature electrical resistance wiring is preferred. The electricallyresistive heating wires may be alloys selected for corrosion resistanceand power dissipation characteristics that allow the wires quickly toheat up and cool down. Suitable exemplary materials for the electricallyresistive heating wires include nichrome and/or calorite. Oneelectrically resistive heating wire suitably disposed within the filtersystem may suffice for effective regeneration. Alternatively, theelectrically resistive heating wire may be a plurality of resistive wiresegments connected in series or in parallel and disposed in differentportions the filter system.

The electrical energy source may be an electrical outlet, a battery, ora generator or alternator or any other device which provides, stores,and/or generates electrical energy.

The electrical connection arrangement includes any wires, bushings,insulators, connectors, switches, or other structures used to transferelectrical energy continuously or recurrently from the electrical energysource to the electrical resistance element. For example, a supply wiremay pass through insulated bushings disposed in the filter housing, thebushing providing electrical and/or thermal insulation.

The heater may also include a control arrangement which controls thesupply of energy to the electrical resistance element, for example, bymeans of timers on a fixed time basis or by means of sensors, such asdifferential pressure sensors or temperature sensors, such asthermocouples, on a variable time basis. For example, a controller, suchas a microprocessor programmed appropriately, may receive temperatureinformation input from a temperature sensor, and/or pressure informationinput from a pressure sensor, and controls the energizing of theelectrical resistance heating elements, based on the microprocessorprogramming and/or sensor information inputs. For example, theelectrically resistive heating wires may all be electrically connectedto the same electrical power source or they may each be electricallyconnected to separate electrical power sources, and may be energizedsubstantially simultaneously or sequentially by means of the controlarrangement. The electrically resistive heating wires may be energizedsequentially via a switching arrangement under control of the controlarrangement. If the energy of the power source is limited, for example,is available only from a vehicular battery, sequential energizing may bedesirable to heat the filter arrangement or the gas in the housing to atemperature high enough to regenerate the filter.

The heater may be operatively associated with the exhaust gas filtersystem in a variety of ways. For example, the heater may be coupled toany of the previously described embodiments of the exhaust gas filtersystem. In the embodiment illustrated in FIG. 20, which is similar tomany of the previous embodiments, the heater preferably comprises anelectrical resistance heating wire 250 electrically coupled to anelectrical energy source 251 via an electrical connection arrangement252. The heater is mounted to the housing 20 and/or the filterarrangement 28 in any suitable manner. For example, the electricalresistance heating wire 250 may be mounted within the inlet pipe 24and/or outlet pipe 26 and/or within the housing 20 in the inlet chamber204, to the baffle 200, between the baffle 200 and the filterarrangement 28, and/or in the outlet chamber 205.

Alternatively or in addition the electrical resistance heating wire 250may be mounted to the filter arrangement 28 at the initiator section 201of the filter elements, to the inlet cells 40, to the filter supports59, to the filter media 57, and/or to the outlet cells 42. Where theelectrical resistance heating wire is mounted to the filter medium, itmay be attached to the upstream face and/or the downstream face of thefilter medium or it may be within the filter medium. Where theelectrical resistance heating wire is mounted to the inlet or outletcells, it may extend between frame members 40a-40d and support members40e, 40f through the interior space or spaces 54 defined by the cell, asshown, for example, in FIG. 21. In addition, the electrical resistanceheating wires 250 may be connected to the electrical energy source 251in series, in parallel or through a switching arrangement S which may,for example, connect each heating wire sequentially, as shown in FIG.20.

As shown in FIG. 22, one or more of the components of the filter systemmay serve as the electrical resistance element, if they are formed froma suitably electrically conductive material. For example, the electricalconnection arrangement 252 may be connected to an inlet cell 40, afilter support 59, the filter medium 57, or an outlet cell 42 which ispreferably electrically insulated from the remainder of the filterassembly. Electrical energy supplied from the source 251 then directlyheats the component to a temperature sufficient to facilitateregeneration of the filter medium.

The heater may similarly be operatively associated with cylindricalembodiments of the filter arrangement. For example, as shown in FIG. 23,electrical resistance heating wires 250 may be mounted to the housing22A and/or the filter arrangement 28A, e.g., in the inlet chamber 204A,to the spacer 84, between the spacer 84 and the filter arrangement 28A,to a filter support 59A, to the filter medium 57A, and/or to the outletchamber 205A. Alternatively, or in addition, suitably conductivecomponents of the filter system may themselves serve as the electricalresistance elements. For example, the electrical connection arrangement252 may be connected directly to the spacer 84, a filter support 59A,and/or the filter medium 57A.

In a preferred mode of operation, exhaust gas is directed through theinlet pipe and the filter arrangement to the outlet pipe, whileparticulates are trapped in the filter medium. Recurrently, the heateris activated to burn particulates off the filter medium and therebyregenerate the filter medium. The heater may be activated, e.g., by thecontrol arrangement, according to any suitable parameter. For example,the heater may be activated on a fixed time basis or a fixed fuelconsumption basis. Alternatively, the differential pressure across thefilter arrangement may be sensed and the heater may be activated oncethe differential pressure exceeds a predetermined value.

Upon activation of the heater, the flow of exhaust gas through thefilter arrangement may be continued or terminated, for example, bydiverting the exhaust gas to a second filter arrangement (not shown).The heater then heats the gas in the housing and/or the components ofthe filter system to a temperature sufficient to facilitate combustionof the particulates in the filter medium. For example, the heater mayincrease the temperature of the particulates sufficient to initiatecombustion of the particulates. Once a combustion is initiated, theheater may be deactivated to conserve energy or it may remain activatedto supplement the heat generated by the combustion of the particulates.In addition, atmospheric air may be introduced into the filterarrangement to enhance combustion of the particulates. For example,atmospheric air may be fed into the filter arrangement via the outletpipe or a separate vent (not shown) by means of a blower (not shown).Alternatively, atmospheric air may be enticed to enter the filterarrangement via the outlet pipe by diverting exhaust gas past the inletpipe through a Venturi tube (not shown), thereby creating a low pressurezone at the inlet pipe.

One the particulates have been burned off the filter media, the heater,if it remained activated, may be deactivated and the flow of exhaustgas, if it was terminated, may be redirected through the regeneratedfilter arrangement.

The present invention has been described above in terms of specificembodiments. It will be readily appreciated by one of ordinary skill inthe art, however, that the invention is not limited to theseembodiments, and that, in fact, the principles of the invention may beembodied and practiced in devices and methods other than thosespecifically described above. Therefore, the invention should not beregarded as being limited to these specific embodiments, but insteadshould be regarded as being fully commensurate in scope with thefollowing claims.

What is claimed is:
 1. An exhaust gas filter assembly for removingparticulates from the exhaust gas of an engine, comprising, incombination,a housing having an inlet pipe configured to receive theexhaust gas from the engine and an outlet pipe configured to ventexhaust gas to the atmosphere and defining an exhaust gas flow paththrough the housing; a filter arrangement disposed in the housing withinthe gas flow path, the filter arrangement including a plurality of inletcells, microporous filter elements, outlet cells which are alternatelyarranged with at least one microporous filter element disposed betweeneach inlet cell and adjacent outlet cell, and wherein the inlet andoutlet cells, and the microporous filter elements comprise materialsthat are resistant to high temperatures such that the filter arrangementmay be regenerated by heat and wherein at least one of the inlet cellsor outlet cells is electrically conductive; and a heater operativelyassociated with the filter arrangement to regenerate the filterarrangement by heating the filter arrangement or gas in the housing tocombust the particulates removed from the exhaust gas of the engine, theheater comprising electrical connection means for electricallyconnecting the electrically conductive inlet cell or outlet cell to anelectrical power source.
 2. The exhaust gas filter assembly of claim 1wherein the housing further includes an inlet chamber communicatingbetween the inlet pipe and the filter arrangement and wherein the heatercomprises an electrically resistive heating wire disposed within theinlet chamber and means for electrically connecting the electricallyresistive heating wire to the electrical power source.
 3. The exhaustgas filter assembly of claim 2 wherein the housing further includes abaffle disposed in the inlet chamber and wherein the electricallyresistive heating wire is mounted to the baffle.
 4. The exhaust gasfilter assembly as claimed in claim 1 wherein the housing includes aninlet chamber and a diffuser baffle disposed in the inlet chamber, thediffuser baffle being comprised of an electrically conductive materialand the heater including means for electrically connecting the diffuserbaffle to the electrical power source.
 5. The exhaust gas filterassembly of claim 4 wherein the baffle is disposed spaced from thefilter arrangement.
 6. The exhaust gas filter assembly of claim 1wherein the heater comprises at least one electrically resistive heatingwire disposed within the filter arrangement and means for electricallyconnecting the electrically resistive heating wire to an electricalpower source.
 7. The exhaust gas filter assembly of claim 6 wherein theelectrically resistive heating wire is mounted to at least one of theinlet or outlet cells.
 8. The exhaust gas filter assembly of claim 6wherein the inlet cells each include frame members defining an internalspace, wherein the outlet cells each include frame members defining aninternal space, and wherein the electrically resistive heating wire isdisposed within the internal space defined by at least one of the inletor outlet cells.
 9. The exhaust gas filter assembly of claim 1 whereinat least one of the filter elements includes an electrically conductivefilter support and a filter medium and wherein the heater compriseselectrical connection means for electrically connecting the electricallyconductive filter support to an electrical power source.
 10. The exhaustgas filter assembly of claim 1 wherein at least one of the filterelements includes a filter support and an electrically conductive filtermedium and wherein the heater comprises electrical connection means forelectrically connecting the electrically conductive filter medium to anelectrical power source.
 11. An exhaust gas filter assembly for removingparticulates from the exhaust gas of an engine, comprising, incombination,a housing having an inlet pipe configured to receive theexhaust gas from the engine and an outlet pipe configured to ventexhaust gas to the atmosphere and defining an exhaust gas flow paththrough the housing; a filter arrangement disposed in the housing withinthe gas flow path, the filtering arrangement including a plurality ofinlet cells, microporous planar filter elements, outlet cells which arealternately arranged with at least one microporous planar filter elementdisposed between each inlet cell and adjacent outlet cell, and whereinthe inlet and outlet cells, and the microporous planar filter elementscomprise materials that are resistant to high temperatures such that thefilter arrangement may be regenerated by heat wherein at least one ofthe filter elements includes a filter support and a filter medium; and aheater operatively associated with the filter arrangement to regeneratethe filter arrangement by heating the filter arrangement or gas in thehousing to combust the particulates removed from the exhaust gas of theengine said heater including an electrically resistive heating wiremounted to the filter support,
 12. An exhaust gas filter assembly forremoving particulates from the exhaust gas of an engine, comprising, incombination,a housing having an inlet pipe configured to receive theexhaust gas from the engine and an outlet pipe configured to ventexhaust gas to the atmosphere and defining an exhaust gas flow paththrough the housing; a filter arrangement disposed in the housing withinthe gas flow path, the filtering arrangement including a plurality ofinlet cells, microporous planar filter elements, outlet cells which arealternately arranged with at least one microporous planar filter elementdisposed between each inlet cell and adjacent outlet cell, and whereinthe inlet and outlet cells, and the microporous planar filter elementscomprise materials that are resistant to high temperature such that thefilter arrangement may be regenerated by heat wherein at least one ofthe filter elements includes a filter support and a filter medium; and aheater operatively associated with the filter arrangement to regeneratethe filter arrangement by heating the filter arrangement or gas in thehousing to combust the particulates removed from the exhaust gas of theengine said heater including an electrically resistive heating wiremounted to the filter medium.
 13. An exhaust gas filter assembly forremoving particulates from the exhaust gas of an engine comprising, incombination,a housing having an inlet pipe configured to receive theexhaust gas from the engine and an outlet pipe configured to ventexhaust gas to the atmosphere and defining an exhaust gas flow paththrough the housing; a filter arrangement disposed in the housing withinthe gas flow path, the filtering arrangement including a plurality ofinlet cells, microporous filter elements, outlet cells which arealternately arranged with at least one microporous filter elementdisposed between each inlet cell and adjacent outlet cell, and whereinthe inlet and outlet cells, and the microporous filter elements comprisematerials that are resistant to high temperature such that the filterarrangement may be regenerated by heat wherein at least one of thefilter elements includes a filter support and a filter medium; and aheater operatively associated with the filter arrangement to regeneratethe filter arrangement by heating the filter arrangement or gas in thehousing to combust the particulates removed from the exhaust gas of theengine said heater including an electrically resistive heating wiredisposed within at least one of the microporous filter elements andmounted to the filter support.
 14. An exhaust gas filter assembly forremoving particulates from the exhaust gas of an engine, comprising incombination,a housing having an inlet pipe configured to receive theexhaust gas from the engine and an outlet pipe configured to ventexhaust gas to the atmosphere and defining an exhaust gas flow paththrough the housing; a filter arrangement disposed in the housing withinthe gas flow path, the filtering arrangement including a plurality ofinlet cells, microporous filter elements, outlet cells which arealternately arranged with at least one microporous filter elementdisposed between each inlet cell and adjacent outlet cell, and whereinthe inlet and outlet cells, and the microporous filter elements comprisematerials that are resistant to high temperatures such that the filterarrangement may be regenerated by heat wherein at least one of thefilter elements includes a filter support and a filter medium; and aheater operatively associated with the filter arrangement to regeneratethe filter arrangement by heating the filter arrangement or gas in thehousing to combust the particulates removed from the exhaust gas of theengine said heater including an electrically resistive heating wiredisposed within at least one of the microporous filter elements andmounted to the filter medium.